Abstract
The self-healing system based on microencapsulated epoxy-amine chemistry is currently the self-healing system with the most practical application potential. It can be widely used in many epoxy-based materials with a size restriction for the microcapsules, such as fiber-reinforced composites, anti-corrosion coatings, etc. Although epoxy microcapsules of different sizes can be fabricated using different techniques, the preparation of polyamine microcapsules with suitable sizes and good performance is the prerequisite for further developing this self-healing system. In this investigation, based on the novel microencapsulation technique via integrating microfluidic T-junction and interfacial polymerization, the feasibility of preparing small-size polyamine microcapsules and the process regulation to optimize the properties of the small-size microcapsules were studied. We show that polyamine microcapsules with sizes smaller than 100 μm can be obtained through the T-junction selection and the feeding rate control of the polyamine. To regulate the small-size microcapsules’ quality, the effects of the concentration of the shell-forming monomer and the solvent with different polarity in the reaction solution and the reaction condition were studied. It shows that dry, free-flowing small-size microcapsules can still be obtained when the shell-forming monomer concentration is higher and the solvent’s polarity is lower, compared with the preparation of larger polyamine microcapsules. Although the change of reaction conditions (reaction temperature and duration) has a certain effect on the microcapsules’ effective core content, it is relatively small. The results of this investigation further promote the potential application of the self-healing systems based on microencapsulated epoxy-amine chemistry in materials with a size restriction for the microcapsules.
Highlights
Polymeric materials suffer from local damages and microcracks inevitably during their life cycle, which cause macrocracks and even fractures to affect their normal use, shorten their service life, and increase safety risk, posing a huge threat to the safety of people’s lives and properties
The feasibility of fabricating small-size polyamine microcapsules was studied by using T-junction T1/T2
Polyamine microcapsules smaller than 100 μm can be achieved by the technique at the cost of the production efficiency by using a lower feeding rate for the polyamine
Summary
Polymeric materials suffer from local damages and microcracks inevitably during their life cycle, which cause macrocracks and even fractures to affect their normal use, shorten their service life, and increase safety risk, posing a huge threat to the safety of people’s lives and properties. Since the self-healing technique has the advantages of extending the service life of materials, improving product safety, and reducing material maintenance costs, it has a wide range of application prospects in the fields of aircraft, automobiles, construction, military equipment, electronic products, etc. Attributed to the ease of preparation of healant carriers, a wide selection of self-healing chemistry, and easy integration with commercial polymer resins, the self-healing systems based on microcapsules are thought to be the most practical self-healing systems among all the developed extrinsic self-healing systems [11,12,13]. The self-healing systems with the potential to be practical applied should have the characteristics of low toxicity, low cost, healing fast and efficiently, matrix compatibility, long-term stability, etc., and have less impact on the performance of the matrix and ease of being integrated with the matrix for specific applications. Considering the limited space among different fibers and different fiber bundles, and between fiber layers, the microcapsule size is a key factor
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